Acyl tosylates synthesis

H-Azepine, 2-methyl-1-methoxycarbonyl-rearrangement, 7, 504 1 //-Azepine, 3-methyl-1 -methoxycarbonyl-cycloaddition reactions, 7, 520 IH-Azepine, 1-phenyl-synthesis, 7, 542 1 H-Azepine, N-phthalimido-formation, 7, 508 IH-Azepine, N-sulfonyl-UV spectra, 7, 501 1 H-Azepine, tetrahydromethylene-synthesis, 7, 540 IH-Azepine, N-p-tosyl-protonation, 7, 509 synthesis, 7, 537 3H-Azepine, 3-acyl-2-alkoxy-synthesis, 7, 542-543 3H-Azepine, 3-acyl-2-methoxy-rearrangements, 7, 505 3H-Azepine, 2-alkoxy-hydrolysis, 7, 510... 

The Hurd-Mori 1,2,3-thiadiazole synthesis is the reaction of thionyl chloride with the N-acylated or tosylated hydrazone derivatives 1 to provide the 1,2,3-thiadiazole 4 in one simple step. ... 

Recent progress of basic and application studies in chitin chemistry was reviewed by Kurita (2001) with emphasis on the controlled modification reactions for the preparation of chitin derivatives. The reactions discussed include hydrolysis of main chain, deacetylation, acylation, M-phthaloylation, tosylation, alkylation, Schiff base formation, reductive alkylation, 0-carboxymethylation, N-carboxyalkylation, silylation, and graft copolymerization. For conducting modification reactions in a facile and controlled manner, some soluble chitin derivatives are convenient. Among soluble precursors, N-phthaloyl chitosan is particularly useful and made possible a series of regioselective and quantitative substitutions that was otherwise difficult. One of the important achievements based on this organosoluble precursor is the synthesis of nonnatural branched polysaccharides that have sugar branches at a specific site of the linear chitin or chitosan backbone [89]. 

The synthesis of 3-aryltetrahydroisoquinolines was accomplished by electrophilic aromatic substitution of polysubstituted phenols and phenyl ethers with Lewis acid-generated tosyliminium ions of 2-tosyl-3-methoxytetrahydroisoquinoline derivatives <00SL801>. In addition isoquinoline was reported to react with N-tosylated (R)- or (S)-amino acid fluorides to afford optically active dihydroimidazoisoquinolinones. The reaction proceeds via acylation followed by attack of the tosylamino group at Cl of the intermediate 2-tosylaminoacylisoquinolinium salt <00TL5479>. 

Although introduced over 40 years ago, Hurd and Mori s synthesis of 1,2,3-thiadiazoles remains the most widely used for the synthesis of 1,2,3-thiadiazoles. The simplicity of the method has contributed to its popularity. A variety of ketones and aldehydes have been converted into their corresponding hydrazones (tosyl and acyl), and thioamides have been converted into thio-carbazonate esters. The carbonyl derivatives are then treated with thionyl chloride to yield 1,2,3-thiadiazoles in high yields. When one is faced with the task of synthesizing new 1,2,3-thiadiazoles, Hurd and Mori s method should always receive attention. 

Construction of a nitrogen six-membered heteroring may be achieved by intramolecular C-acylation. This pathway was used, for instance, in the synthesis of l//-naphtho[hc]pyridine-2,3-dione 329 from N-tosyl-N-(a-naphthyl)aminooxallyl chloride 328 (28USP1698894). Approaches to 1H-... 

Difluoro-l-(tosyloxy)vinyllithium 586 has been employed as an acyl anion equivalent of the type 587. This anion was prepared by treatment of 2,2,2-trifluoroethyl tosylate with two equiv of LDA at —78 °C860 (Scheme 159). The reaction of intermediate 586 with carbonyl compounds, followed by acid hydrolysis, gave compounds 588 which, after basic treatment with sodium hydroxide, afforded ct-keto acids 589. The reaction of the intermediate 586 with boranes provided the corresponding borates, which have been used in the synthesis of fluorinated molecules861. 

Additional flexibility in the control over the selectivity of heterolytic reactions is provided in the diversity of electrophilic reagents that formally correspond to the same electrophile. For example, reagents such as RCO BF, RCOO-SO2CF3, RCOCl, and (RC0)20 are employed in synthesis as equivalents of the acyl cation RCO. However, a tremendous difference in the reactivity of these acylating species enables one to choose a reagent specifically adjusted to the peculiarity of the nucleophilic counterpart. In a similar way, such unlike compounds as trialkyloxonium salts, R30 BF7, alkyl halides, tosylates, or acetates can serve as transfer agents of the same alkyl cation, R, but they differ drastically in their activity and pattern of selectivity toward various nucleophiles. 

Preparative Methods several methods for the synthesis of this ligand have been reported. The preparation usually starts with the reduction of commercially available (iS)-terf-leucine to the corresponding amino alcohol, followed by acylation with 0.5 equiv of dimethylmalonyl dichloride. The resulting dihydroxy malonodiamide is cyclized via the bis(alkyl chloride) or via the bis(tosylate) as described in an improved procedure (eq 1). ... 

The synthesis can be extended to the preparation of ketones in six distinct ways. " These include quenching 180 with a second alkyl halide (R X) rather than acetic acid omitting PPhs with first RX and then adding the second, R X treatment with RX in the presence of CO, followed by treatment with R X treatment with an acyl halide followed by treatment with an alkyl hahde or an epoxide, gives an a,p-unsaturated ketone. The final variations involve reaction of alkyl halides or tosylates with Na2Fe(CO)4 in the presence of ethylene to give alkyl ethyl ketones when 1,4-dihalides are used, five-mem-... 

A related triazole synthesis utilizes phosphorous ylids, such as 264. The initially formed triazenes cyclize with elimination of triphenylphosphine oxide. The reaction proceeded sluggishly with phenyl azide, but good results have been obtained with acyl or sulphonyl azides. Tosyl azide and 264 yielded 98% of the 1-tosyl-triazole 265. The tosyl group could be removed by solvolysis in boiling ethanol... 

Tosylmethyl isocyanide (TosMIC) (75 R = H), a versatile reagent in synthesis, can also be used as an acyl anion equivalent. For instance symmetrical and unsymmetrical diketones were prepared by using this TosMIC synthon (equation 40). Ketones are homologated to enones by alkylating the condensation product derived from TosMIC, followed by acid hydrolysis (Scheme 46). 1-Isocyano-l-tosyl-l-alkenes (76), formed by the reaction of TosMIC with an aldehyde or ketone, react with a primary amine or ammonia to give 1,5-disubstituted (or 5-monosubstituted) imidazoles in high yield (Scheme 47). ... 

---